Chip holder

ABSTRACT

A rotating shaft ( 23 ) is inserted through an axial center of a cutter wheel chip for scribing a brittle object. The rotating shaft ( 23 ) is integrally provided with the cutter wheel chip. The rotating shaft ( 23 ) is inserted into supporting holes ( 14 ) provided in side walls ( 11 ) of a chip holder ( 11 ) so as to be supported. A groove ( 13 ) is formed in an upper portion of each supporting hole ( 14 ) along an axial direction of the supporting hole ( 14 ).

TECHNICAL FIELD

The present invention relates to a chip holder for holding a cutterwheel chip in a wheel cutter used, for example, for scribing or scoringbrittle materials such as, glass, for example.

BACKGROUND ART

A glass plate used for a liquid crystal display panel or the like isusually produced by first scribing a large mother glass plate with awheel cutter so as to form scribe lines, and then cutting the motherglass plate along the scribe lines into pieces of a prescribed size. Thewheel cutter includes a circular cutter wheel chip held by a chipholder.

The cutter wheel chip is circular, has an outer circumferential surface,and is formed of a hard metal, sintered diamond or the like. A center ofthe entire outer circumferential surface projects in such a manner so asto be sharp and acts as a blade edge.

The cutter wheel chip has a hole at an axial center thereof, and arotating shaft is passed through the hole. The hole has a diameter whichis slightly larger than the diameter of the rotating shaft, such thatthe cutter wheel chip is freely rotatable with respect to the rotatingshaft.

Each of two side portions of the rotating shaft are respectivelysupported by a pair of walls included in the chip holder. The cutterwheel chip is located between the walls. The two side portions of therotating shaft are inserted into supporting holes of the walls.

FIG. 16 is a cross-sectional view of such a rotating shaft 33 which issupported by the walls. As shown in FIG. 16, each of two side portions(only one is shown) of the rotating shaft 33 is inserted into asupporting hole 34 formed in a wall 31 to be supported. The innerdiameter of the supporting hole 34 is slightly larger than the outerdiameter of the rotating shaft 33, so that there is a slight tolerance Gbetween an inner circumferential surface of the supporting hole 34 andan outer circumferential surface of the rotating shaft 33.

For scribing a brittle object such as a glass plate or the like, thewheel cutter is moved with respect to the brittle object in a prescribedscribing direction. The cutter wheel chip runs on a surface of thebrittle object so as to be pressed thereon. In this state, the wheelcutter keeps on moving on the surface in the prescribed scribingdirection.

When the cutter wheel chip runs on the brittle object, a force isapplied on the cutter wheel chip and also on the rotating shaft 33engaged with the cutter wheel chip. When the cutter wheel chip ispressed on the brittle object, the rotating shaft 33 is elevated andpressed on an upper portion of the inner circumferential surface of thesupporting hole 34.

The rotating shaft 33 contacts the upper portion of the innercircumferential surface of the supporting hole 34 at one contact line Y.In this state, the entire reaction force from the inner circumferentialsurface of the supporting hole 34 is applied on the rotating shaft 33 atcontact line Y. When impact is applied on the cutter wheel chip, theimpact is also applied on the rotating shaft 33 engaged with the cutterwheel chip. Then, a reaction force from the entire inner circumferentialsurface of the supporting hole 34 is applied on the rotating shaft 33 atcontact line Y . As a result, the rotating shaft 33 can be undesirablybroken at contact line Y.

When the cutter wheel chip pressed on the surface of the brittle objectmoves on the surface, a frictional force is applied on the rotatingshaft 33 due to a reaction force applied on the rotating shaft 33 fromthe inner circumferential surface of the supporting hole 34, thusrestricting the rotation of the rotating shaft 33. The cutter wheel chiprotates with respect to the rotating shaft 33, and thus the edge of thecutter wheel chip, rotatably engaged with the rotating shaft 34, moveswhile rotating in contact with the surface of the brittle object. Thus,the surface of the brittle object is scribed.

The conventional cutter wheel having the above-described structure hasthe following problems. The rotating shaft 33 has substantially the sameouter diameter as the inner diameter of the supporting hole 34.Therefore, it is possible that the reaction force applied on therotating shaft 33 from the inner circumferential surface of thesupporting hole 34 is too low to stop the rotation of the rotating shaft33 with certainty, resulting in the rotating shaft 33 slipping and thusfurther rotating undesirably. Especially when the pressure contact forcebetween the supporting hole 34 and the rotating shaft 33 changes due toa change in the pressing force of the cutter wheel chip on the surfaceof the brittle object which occurs during the scribing operation, or dueto a change in the scribing speed of the cutter wheel chip, thepossibility of the rotating shaft 33 slipping so as to rotate on thebrittle object surface increases.

When the rotating shaft 33 slips and rotates, the resistance caused byfriction between an outer circumferential surface of the rotating shaft33 and an inner circumferential surface of the cutter wheel chip havinga slightly larger diameter than the diameter of the rotating shaft 33becomes unstable. This may undesirably result in the quality of thescribe lines being non-uniform.

Since the rotating shaft 33 slips, the outer circumferential surface ofthe rotating shaft 33 and the inner circumferential surface of thesupporting hole 34 are abraded, which may undesirably prevent long andstable use of the wheel cutter.

When the rotating shaft 33 slips, a force is applied on the rotatingshaft 33 from the inner circumferential surface of the supporting hole34 in an abnormal direction, which may undesirably damage the rotatingshaft 33.

The present invention, for solving the above-described problems, has anobjective of providing a chip holder for realizing long and stable useof a rotating shaft engaged with a cutter wheel chip.

Another objective of the present invention is to provide a chip holderfor allowing the cutter wheel chip to stably scribe a surface of abrittle object.

DISCLOSURE OF THE INVENTION

A chip holder according to the present invention, for holding a rotatingshaft which is inserted through an axial center of a cutter wheel chipfor scribing a brittle object, includes supporting holes into which sideportions of the rotating shaft are respectively inserted; and groovesrespectively provided along the supporting holes.

In one embodiment of the invention, the grooves have a V-shaped orquadrangular cross-section.

In one embodiment of the invention, the supporting holes have a circularor elliptical cross-section.

In one embodiment of the invention, the supporting holes have apolygonal cross-section, and the grooves are defined by one of thecorners of the polygon.

In one embodiment of the invention, the grooves are provided on a sideopposite to a direction in which the cutter wheel chip moves forscribing, the grooves being at an angle of 0 to 60 degrees with respectto a vertical line passing through the center of across-section of thesupporting holes.

In one embodiment of the invention, the supporting holes for supportingthe side portions of the rotating shaft have an equal length in an axialdirection thereof.

In one embodiment of the invention, the supporting holes for supportingthe side portions of the rotating shaft have different lengths in anaxial direction thereof.

In one embodiment of the invention, the supporting holes arerespectively provided in side walls which are located so as to interposethe cutter wheel chip therebetween, and the chip holder furthercomprises a chip receiver for preventing the cutter wheel chip fromabrading due to contact with the side walls, the chip receiver beingprovided on a face of each side wall facing the cutter wheel chip.

In one embodiment of the invention, the chip receivers are ring-shapedso as to surround the respective supporting holes.

In one embodiment of the invention, the chip receivers each have agroove on a face thereof facing the cutter wheel chip.

In one embodiment of the invention, the chip receivers are provided inthe side walls, and the supporting holds are formed in the chipreceivers.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a partially cut side view of one example of a wheel cutterincluding a chip holder according to the present invention.

FIG. 2 is a partially cut front view illustrating an example of the chipholder provided in the wheel cutter.

FIG. 3 is a partial cross-sectional view of the chip holder.

FIGS. 4A and 4B are cross-sectional views of a chip holder illustratinghow a force applied on a rotating shaft is exerted against an innercircumferential surface of a supporting hole.

FIG. 5 is a partial cross-sectional view illustrating another example ofa chip holder according to the present invention.

FIG. 6 is a partial cross-sectional view illustrating still anotherexample of a chip holder according to the present invention.

FIG. 7 is a partial cross-sectional view illustrating still anotherexample of a chip holder according to the present invention.

FIG. 8 is a partial cross-sectional view illustrating still anotherexample of a chip holder according to the present invention.

FIG. 9 is a partial cross-sectional view illustrating still anotherexample of a chip holder according to the present invention.

FIG. 10 is a partially cut front view illustrating still another exampleof a chip holder according to the present invention.

FIG. 11 is a partially cut front view illustrating still another exampleof a chip holder according to the present invention.

FIG. 12 is a partially cut front view illustrating still another exampleof a chip holder according to the present invention.

FIG. 13A is a partially cut side view illustrating still another exampleof a chip holder according to the present invention; FIG. 13B is across-sectional view of the chip holder shown in FIG. 13A; and FIG. 13Cis an enlarged view of a part of the chip holder shown in FIG. 13B.

FIG. 14A is an enlarged front view illustrating still another example ofa chip holder according to the present invention; and FIG. 14B is a sideview of the chip holder shown in FIG. 14A seen in the direction of arrowB in FIG. 14A.

FIG. 15A is a partially cut side view illustrating still another exampleof a chip holder according to the present invention; FIG. 15B is across-sectional view of the chip holder shown in FIG. 15A; and FIG. 15Cis an enlarged view of a part of the chip holder shown in FIG. 15B.

FIG. 16 is an enlarged cross-sectional view of a part of a conventionalchip holder.

FIG. 17 shows a table representing the ratio of the force f applied oneach of borders Y1 and Y2 with respect to the force P applied on therotating shaft when angle a is changed in expression (1).

BEST MODE FOR CARRYING OUT THE INVENTION

Hereinafter, the present invention will be described by way ofillustrative examples with reference to the accompanying drawings.

FIG. 1 is a partially cut side view of a wheel cutter 1 including a chipholder 10 according to one example of the present invention, and FIG. 2is a partially cut front view of the wheel cutter 1. The wheel cutter 1includes a cutter wheel chip 22 used for scribing a brittle object suchas, for example, a glass plate, and the chip holder 10 for holding thecutter wheel chip 22.

The cutter wheel chip 22 is circular, has an outer circumferentialsurface, and is formed of a hard metal, sintered diamond or the like. Acenter of the entire outer circumferential surface is projecting in sucha manner so as to have an obtuse angle and acts as a blade edge.

The cutter wheel chip 22 has a hole at an axial center thereof, and arotating shaft 23 is passed through the hole. The hole has a diameterwhich is slightly larger than the diameter of the rotating shaft 23,such that the cutter wheel chip 22 is freely rotatable with respect tothe rotating shaft 23. The rotating shaft 23 projects from the cutterwheel chip 22 in two opposite directions by an equal length.

Each of two ends of the rotating shaft 23 has a cone-like shape having adiameter which gradually reduces toward a tip thereof. Each tip islocated on the axis of the rotating shaft 23.

The chip holder 10 for holding the cutter wheel chip 22 includes a topportion 12 which is provided below a supporting shaft 27 and a pair ofside walls 11 (only one is shown in FIG. 1) extending from andperpendicularly to the top portion 12. The side walls 11 are separatedfrom each other by an appropriate distance. The side walls 11 each havea uniform thickness, and one of the side walls 11 is thicker than theother. Each side wall 11 has a triangular shape having a graduallyreduced width toward a bottom thereof as shown in FIG. 1.

The supporting shaft 27 is rotatable about a vertical axis thereof by abearing 28, and is loaded downward (toward the chip holder 10) by anappropriate loading member.

The cutter wheel chip 22 is located between the side walls 11 of thechip holder 10.

Each side wall 11 has a horizontal supporting hole 14 for supporting therotating shaft 23 inserted through the center of the cutter wheel chip22. Each projecting side portion of the rotating shaft 23 is insertedinto the corresponding supporting hole 14. The supporting holes 14 ofthe side walls 11 are concentric and have an equal diameter. Thediameter of each supporting hole 14 is slightly larger than that of therotating shaft 23 such that the rotating shaft 23 is rotatable. Thesupporting holes 14 have an equal length in an axial direction thereof.

In the state where the side portions of the rotating shaft 23 areinserted into the supporting holes 14, the cutter wheel chip 22 projectsdownward from a bottom surface of the side walls 11 by a prescribeddistance.

One of the side walls 11 has a pin hole 19 in communication with thesupporting hole 14 at an opposite end of the supporting hole 14 from thecutter wheel chip 22. The pin hole 19 has a smaller diameter than thatof the supporting hole 14, and is concentric with the supporting hole14. The tip of one of the cone-like ends of the rotating shaft 23 isconcentrically inserted into the pin hole 19 and is supported so as tobe rotatable.

The other supporting hole 14 passes through the side wall 11 up to anouter surface of the side wall 11. The outer surface of the side wall 11has an opening in communication with the supporting hole 14. The tip ofthe cone-like end of the rotating shaft 23 is located in the opening. Aclosing plate 15 for closing the opening is provided on the outersurface of the side wall 11. The closing plate 15 is attached to theside wall 11 with a screw 16 provided on a top portion of the closingplate 15. A bottom portion of the closing plate 15 closes the opening,and contacts the tip of the rotating shaft 23 so as to prevent therotating shaft 23 from coming out of the supporting hole 14.

As described above, the supporting holes 14 in the side walls 11 have anequal length, and one of the side walls 11 has the pin hole 19.Therefore, the side wall 11 having the pin hole 19 is thicker than theother side wall 11 as previously defined.

The top portion 12 is attached to the supporting shaft 27 so that theaxis of the supporting shaft 27 is appropriately offset from a verticalline passing through the center of the cutter wheel chip 22, the centerbeing in the axial direction. Therefore, the cutter wheel chip 22 canrotate about the axis of the supporting shaft 27.

For replacing the cutter wheel chip 22 with a new one, the chip holder10 is handled as follows. The closing plate 15 is pivoted about thescrew 16 so as to expose the opening in the side wall 11. Then, a pin isinserted through the pin hole 19 from the outside of the chip holder 10so that the rotating shaft 23 in the supporting hole 14, incommunication with the pin hole 19, is pressed by the pin. Thus, therotating shaft 23 slides in the supporting holes 14 in the axialdirection thereof. In this manner, the rotating shaft 23 comes off fromthe cutter wheel chip 22 and then comes outside the side wall 11 throughthe opening.

After the cutter wheel chip 22 is replaced with a new one, the rotatingshaft 23 is inserted into the supporting hole 14 from the opening of oneside wall 11 and into the new cutter wheel chip 22.

FIG. 3 is a cross-sectional view of FIG. 2 taken along lines A-A in FIG.2. The following description relates to one side of the chip holder 10unless otherwise specified. The side wall 11 has a groove 13 above andcontinuous from the supporting hole 14 in the axial direction of thesupporting hole 14. The groove 13 has a V-shaped cross-section andprojects outward from the supporting hole 14. The groove 13 is providedon a side opposite to the direction in which the wheel cutter 1 is movedon the surface of the brittle object such as, for example, a glassplate.

The groove 13 is defined by a pair of inner faces 13 a lying along atangent of an inner circumferential surface of the supporting hole 14.An angle made by the inner faces 13 a is set so that the groove 13 has aprescribed depth. The angle is set to, for example, 120 degrees.

The groove 13 is provided so that a bisector of the angle made by theinner faces 13 a matches a line which makes a prescribed angle θ with avertical line C passing through the center of the supporting hole 14.The angle θ is set to an angle in the range of 0 to 60 degrees, forexample, 30 degrees.

In this example, the diameter of the rotating shaft 23 is 0.8 mm, thelength L1 (FIG. 2) of the rotating shaft 23 is 6 mm, the diameter of thesupporting hole 14 is about 0.02 mm to 0.04 mm larger than 0.8 mm, andthe depth d of the groove 13 is 0.06 mm. The closing plate 15 is formedof a stainless steel plate having a thickness of 0.5 mm.

For scribing a brittle object, the wheel cutter 1 having theabove-described structure is moved in a scribing direction relative tothe brittle object, with the chip holder 10 being loaded downward. Then,the cutter wheel chip 22 runs on the surface of the brittle object. Thecutter wheel chip 22 is pressed on the surface of the brittle object bythe force loading the entire chip holder 10 downward and moves in thescribing direction while rotating in contact with the surface.

When the cutter wheel chip 22 runs on the surface, impact is applied onthe cutter wheel chip 22, and also on the rotating shaft 23 engaged withthe cutter wheel chip 22. When the cutter wheel chip 22 is pressed onthe surface, the rotating shaft 23 is elevated and pressed on an upperportion of the inner circumferential surface of the supporting hole 14.

The side wall 11 has the groove 13 in an upper area thereof facing therotating shaft 23, the 13 projecting outward from the supporting hole 14and having a V-shaped cross-section. Therefore, the rotating shaft 23contacts borders Y1 and Y2 between the inner faces 13 a and thesupporting hole 14. Therefore, the reaction force from the entire innercircumferential surface of the supporting hole 14 is applied on therotating shaft 23 at both the borders Y1 and Y2 in a divided state. As aresult, the force applied on the rotating shaft 23 at each border Y1, Y2is alleviated without being concentrated on any one specific portion.

Even though impact is applied on the chip holder 10 when the cutterwheel chip 22 runs on the brittle object, the impact applied on therotating shaft 23 is alleviated.

Even when the impact is applied on the chip holder 10 in a directionrepresented by arrow Y3 or Y4 (FIG. 3), the impact is applied on therotating shaft 23 at the borders Y1 and Y2 in a divided state.Therefore, the impact applied on the rotating shaft 23 is alleviatedregardless of the direction in which the impact is applied on the chipholder 10.

Due to this alleviation of the impact applied on the rotating shaft 23,the durability of the rotating shaft 23 is significantly improved.

While the cutter wheel chip 22 moves while rotating in contact with thesurface of the brittle object, a frictional force applied on therotating shaft 23 from the inner circumferential surface of thesupporting hole 14 is applied at the two borders Y1 and Y2. Thus, therotation of the rotating shaft 23 is locked with certainty. The cutterwheel chip 22 rotates with respect to the stopped rotating shaft 23 witha certain resistance caused by friction, and moves while rotating incontact with the surface of the brittle object. As a result, the cutterwheel chip 22 stably scribes the surface of the brittle object and formsscribe lines of a uniform quality.

Since the rotation of the rotating shaft 23 can be locked withcertainty, the rotating shaft 23 is prevented from being non-uniformlyworn by the inner circumferential surface of the supporting hole 14.

The rotating force of the cutter wheel chip 22 for running on thesurface of the brittle object also causes the rotating shaft 23 toslightly rotate. Therefore, the positional relationship of the outercircumferential surface of the rotating shaft 23 changes with respect tothe inner circumferential surface of the cutter wheel chip 22 each timea different brittle object is scribed. Thus, the rotating shaft 23 andthe cutter wheel chip 22, both formed of a hard metal or the like, areprevented or alleviated from becoming immovable with respect to eachother due to the friction between the inner circumferential surface ofthe cutter wheel chip 22 and the outer circumferential surface of therotating shaft 23.

Hereinafter, it will be described in more detail that the groove 13alleviates the force applied on the rotating shaft 23. FIG. 4A shows astate in which an upward force P is applied on the rotating shaft 23with no groove being provided. More specifically, the rotating shaft 23and the inner circumferential surface of the side wall 11 contact eachother at one line, and the force P is applied on the rotating shaft 23as a reaction force from the inner circumferential surface of thesupporting hole 14.

FIG. 4B shows a state where the groove 13 having a V-shapedcross-section projecting outward from the supporting hole 14 is formed.A bisector of the angle made by the inner faces 13 a matches thevertical line passing through the center of the supporting hole 14. Inthis state, the upward force P applied on the rotating shaft 23 isdivided into a force applied to the border Y1 and a force applied to theborder Y2.

Where ½ of the angle made by the inner faces 13 a is α as shown in FIG.4B, a force f applied to each of the borders Y1 and Y2 is represented byexpression (1).f=(P·sin α)/2  (1)

Table 1 provided in FIG. 17 shows the ratio of the force f applied toeach of the borders Y1 and Y2 with respect to the force P applied to therotating shaft 23 in accordance with the angle α from expression (1).

It is appreciated from Table 1 that when a is 45 degrees, the ratio ofthe force 2f with respect to the force P is 0.354·P and thus theresistance of the rotating shaft 23 against impact is 1/0.354 times,i.e., about 2.8 times, the resistance when the groove 13 is not formed.This calculated value tends to be significantly close to the actuallymeasured value although not exactly the same.

As described above, in the case where the side wall 11 does not have thegroove 13, the rotating shaft 23 and the side wall 11 contact each otherat one line. Therefore, the reaction force applied from the innercircumferential surface of the supporting hole 14 on the rotating shaft23 is concentrated on that one line. In the case where the side wall 11has the groove 13, the rotating shaft 23 and the side wall 11 contacteach other at two lines. Therefore, the reaction force applied from theinner circumferential surface of the supporting hole 14 on the rotatingshaft 23 is divided into two. As a result, the resistance of therotating shaft 23 against impact is improved, thus eliminating theundesirable possibility of the rotating shaft 23 being broken.

When the wheel cutter 1 (FIG. 2) scribes a glass plate, the lowermostpoint of the cutter wheel chip 22 is usually set to be about 0.12 mm toabout 0.20 mm below the surface of the glass plate in the state wherethe cutter wheel chip 22 is loaded downward. Thus, the cutter wheel chip22 is pressure-contacted onto the surface. Where the cutter wheel chip22 eats into the surface of the glass plate by less than 0.02 mm, therotating shaft 23 is pressed upward vertically by about 0.1 mm to about0.18 mm. Where the angle θ between the bisector of the angle made by twoinner faces 13 a (FIG. 3) and the vertical line passing through thecenter of the supporting hole 14 is in the range of 0 to 60 degrees, thedistance by which the rotating shaft 23 is pressed up in the verticaldirection is 0.05 mm to 0.09 mm when θ=60 degrees, which is the minimumpossible value.

FIG. 5 shows a structure in which the groove 13 has a rectangularcross-section. The groove 13 is formed along the axial direction of thesupporting hole 14. A bisector CL1 of the groove 13 which divides thewidth W of the groove 13 matches a line extending in a radial directionfrom the center of the supporting hole 14. The groove 13 is formed sothat, for example, an angle θ made by the bisector CL1 and the verticalline passing through the center of the supporting hole 14 is 30 degrees.The groove 13 has a width W of, for example, 0.4 mm and a depth d of,for example, 0.1 mm.

In this case also, the rotating shaft 23 and the side wall 11 contacteach other at borders Y5 and Y6 between the inner faces 13 a and thesupporting hole 14. Therefore, the rotation of the rotating shaft 23 islocked with certainty, and thus the cutter wheel chip 22 smoothlyrotates without slipping with respect to the rotating shaft 23. Thecutter wheel chip 22 moves while rotating in contact with the surface ofa brittle object and stably forms a scribe line in the surface.

The impact applied on the rotating shaft 23 from the innercircumferential surface of the supporting hole 14 is alleviated, whichrealizes a long and stable use of the rotating shaft 23.

FIG. 6 shows a structure in which the supporting hole 14 has anelliptical cross-section. The longer axis of the ellipticalcross-section is at an angle of θ (θ=0 to 60 degrees) with respect tothe vertical line passing through the center of the supporting hole 14.The groove 13 having a V-shaped cross-section is formed above andcontinuous from the supporting hole 14. A bisector of an angle made bythe inner faces 13 a matches the longer axis of the ellipticalcross-section.

In this structure, the rotating shaft 23 can move vertically by a largerdistance than for the circular cross-sectioned supporting hole 14.Therefore, the cutter wheel chip 22 of the chip holder 10 (FIG. 1) mayproject downward from the bottom surface of the side wall 11 by as muchas 1 mm or more. Still, the lowermost point of the cutter wheel chip 22can be set to be about 0.2 mm to about 0.9 mm below the surface of thebrittle object.

The supporting hole 14 may have a polygonal cross-section instead of acircular or elliptical cross-section. In the case where the supportinghole 14 has a polygonal cross-section, the groove 13 is defined by onecorner of the polygon. Two adjacent sides of the polygon interposing thecorner defining the groove 13 act as inner faces 13 a. The rotatingshaft 23 is pressure-contacted on these two sides.

FIG. 7 shows a structure in which the supporting hole 14 has apentagonal cross-section. The groove 13 having a V-shaped cross-sectionis defined by one of the five corners. In this case also, a bisector ofthe corner defining the groove 13 is at an angle of θ (θ=0 to 60degrees) with respect to the vertical line passing through thesupporting hole 14.

FIG. 8 shows a structure in which the supporting hole 14 has atriangular cross-section. The groove 13 having a V-shaped cross-sectionis defined by one of the three corners. In this case also, a bisector ofthe corner defining the groove 13 is at an angle of θ (θ=0 to 60degrees) with respect to the vertical line passing through thesupporting hole 14.

FIG. 9 shows a structure in which the supporting hole 14 has a hexagonalcross-section. The groove 13 having a V-shaped cross-section is definedby one of the six corners. In this case also, a bisector of the cornerdefining the groove 13 is at an angle of θ (θ=0 to 60 degrees) withrespect to the vertical line passing through the supporting hole 14.

The supporting hole 14, when having a polygonal cross-section,preferably has a triangular, a quadrangular, a pentagonal, a hexagonal,a heptagonal or an octagonal cross-section. When the number of cornersexceeds eight, the pressure-contacting force of the inner faces 13 adefining the groove 13 applied on the rotating shaft 23 may be too smallso as to lock the rotation of the rotating shaft 23.

FIG. 10 is a partially cut cross-sectional view illustrating anotherexemplary structure of a chip holder 10 according to the presentinvention. In the chip holder shown in FIG. 10, the two side walls 11have an equal width. The two supporting holes 14 pass through therespective side walls 11 up to the outer surfaces of the side walls 11.The rotating shaft 23 projects from the cutter wheel chip 22 in twoopposite directions by an equal length.

A closing plate 15 for closing each opening is provided on each outersurface of each side wall 11. The closing plate 15 is attached to theside wall 11 with a screw 16 provided on a top portion of the closingplate 15. A bottom portion of the closing plate 15 closes the opening,and contacts the tip of the rotating shaft 23 so as to prevent therotating shaft 23 from coming out of the supporting hole 14.

The chip holder shown in FIG. 10 is identical with that of the chipholder 10 shown in FIG. 2 except for the above-described points. Sincethe supporting holes 14 in the side walls 11 support side portions ofthe rotating shaft 23 of an equal length, the rotating shaft 23 isstably supported. Thus, the cutter wheel chip 22 engaged with therotating shaft 23 stably rotates.

FIG. 11 is a partially cut cross-sectional view illustrating stillanother exemplary structure of a chip holder 10 according to the presentinvention. In the chip holder shown in FIG. 11, the two side walls 11have an equal thickness. One of the side walls 11 has a pin hole f19 incommunication with the supporting hole 14. The structure of the chipholder shown in FIG. 11 is identical with that of the chip holder 10shown in FIG. 2 except for the above-described points.

As shown in FIG. 11, one of the supporting holes 14 which is incommunication with the pin hole 19 is shorter than the other.Accordingly, the cutter wheel chip 22 is engaged with the rotating shaft23 at a point closer to one of the ends thereof, so that one of the sideportions of the rotating shaft 23 is supported by the shorter supportinghole 14.

In this structure, when the side portion of the rotating shaft 23 whichis supported by the shorter supporting hole 14 is worn, the two sideportions of the rotating shaft 23 are exchanged with each other, and thecutter wheel chip 22 is engaged with the rotating shaft 23 at adifferent position. Then, the worn portion of the rotating shaft 23 islocated in the longer supporting hole 14. Since the cutter wheel chip 22is now engaged with the rotating shaft 23 at the different position, apart which is not worn is also located in the longer supporting hole 14.Therefore, the rotating shaft 23 can be used for a longer time.

FIG. 12 is a partially cut cross-sectional view illustrating stillanother exemplary structure of a chip holder 10 according to the presentinvention. In the chip holder 10 shown in FIG. 12, one of the two sidewalls 11 is thicker than the other. The structure of the chip holder 10shown in FIG. 12 is identical with that of the chip holder 10 shown inFIG. 10 except for the above-described points. The chip holder 10 shownin FIG. 12 can be used for a longer time for the same reason as thatdescribed above regarding the chip holder shown in FIG. 11.

FIG. 13A is a side view of a chip holder 20 according to another exampleof the present invention. FIG. 13B is a cross-sectional view thereof,and FIG. 13C is an enlarged view of a part thereof. The chip holder 20has a similar structure to that of the chip holder 10 shown in FIG. 2,except that a ring-shaped chip receiver 17 is provided on an innerportion of each side wall 11 facing the cutter wheel chip 22. Thering-shaped chip receiver 17 is provided so as to surround therespective supporting hole 14. Each chip receiver 17 is formed of a hardmetal. The rotating shaft 23 is inserted through the chip receiver 17and then into the supporting hole 14. The chip receivers 17 slidablycontact respective side surfaces of the cutter wheel chip 22, which isfreely rotatable with respect to the rotating shaft 23. Thus, the chipreceivers 17 prevents the cutter wheel chip 22 from moving along theaxial direction of the rotation shaft 23.

In this structure, the chip receivers 17 protect the side surfaces ofthe cutter wheel chip 22 from directly contacting the inner surfaces ofthe side walls 11. Thus, the inner surfaces of the side walls 11 areprevented from being worn. The chip receivers 17 also stabilize therotation of the cutter wheel chip 22, which, in turn, scribes thesurface of a brittle object more stably.

Each chip receiver 17 is provided in, for example, the following manner.A hard metal cylinder, having an outer diameter which is larger than thediameter of the supporting hole 14 and an inner diameter which is alsoslightly larger than the diameter of the supporting hole 14, is cut intoa piece having a thickness of about 0.5 mm. This piece is used as a chipreceiver 17. The chip receiver 17 is aligned around the supporting hole14 such that the center of the supporting hole 14 matches the center ofthe inner hole of the chip receiver 17, and then is silver-solderedaround the supporting hole 14. A face of the chip receiver 17 which isto contact the cutter wheel chip 22 is polished by a diamond grinder orthe like.

FIG. 14A is a side view illustrating another exemplary structure of achip holder according to the present invention. FIG. 14B is a view of aportion of the chip receiver 17 seen in the direction of arrow B in FIG.14A. As shown in FIGS. 14A and 14B, an inner face of each chip receiver17 has grooves 17 a extending from the central hole thereof in ahorizontal direction and a vertical direction. Due to this structure,cullet, dust or the like generated while the brittle object is scribedis scattered through the grooves 17 a. Therefore, the cullet, dust orthe like is prevented from concentrating on the edge of the cutter wheelchip 22. As a result, the brittle object can be stably scribed, and theedge of the cutter wheel chip 22 can be used for a longer time. Thegrooves 17 a may be extended in any radial direction from the centralhole of the chip receiver 17, instead of the horizontal or verticaldirection. The grooves 17 a may be provided in a lattice surrounding thecentral hole of the chip receiver 17.

The chip holder 20 shown in FIGS. 13A, 13B and 13C is produced byconnecting upper portions of two side walls together with two screws 18so as to form the top portion 12. The side walls 11 and the top portion12 may be integrally formed of a material having an excellent abrasionresistance such as, for example, a hard metal, sintered diamond,diamond-dispersed hard metal, and CBN (cubic boron nitride). When theside walls 11 and the top portion 12 are integrally formed, the chipholder is alleviated from deformation caused by impact due to, forexample, scribing. Thus, the chip holder can stably hold the cutterwheel chip for a longer time, and therefore allows the cutter wheel chip22 to scribe a brittle object stably for a longer time.

FIG. 15A is a side view of a chip holder 30 according to still anotherexample of the present invention. FIG. 15B is a dross-sectional viewthereof, and FIG. 15C is an enlarged view of a part thereof. The sidewalls 11 and the top portion 12 are integrally formed of a metalmaterial such as, for example, SK. Each chip receiver 17 is formed of amaterial having an excellent abrasion resistance such as, for example, ahard metal, sintered diamond, diamond-dispersed hard metal, and CBN.Each side wall 11 has a through-hole in a bottom portion thereof, andthe chip receiver 17 is integrally provided in the through-hole. Thecentral hole of the chip receiver 17 acts as the supporting hole 14. Theside walls 11 each have a groove 13 projecting outward from thesupporting hole 14 along the axial direction thereof. The chip receiver17 projects inward from the inner face of the side wall 11 by anappropriate length, and the projecting end of the chip receiver 17contacts the respective side surface of the cutter wheel chip 22.

The chip holder 30 having such a structure is produced, for example, asfollows. A metal block formed of hard metal, an SK material, or the likehaving a prescribed shape is prepared. A The block does not have a gapin which the cutter wheel chip 22 is to be located. A through-hole inwhich the chip receivers 17 are to be located is formed in a thicknessdirection E in a bottom portion of the block. A cylinder to be used asthe chip receivers 17 is inserted into the through-hole andsilver-soldered on an inner circumferential surface of the block. Athrough-hole to act as the supporting holes 14 is formed through thecenter hole of the cylinder by wire discharge. The groove 13 is formedso as to project outward from the through-hole in the axial directionthereof. A gap in which the cutter wheel chip 22 is to be located isformed, thereby forming the side walls 11. Thus, the chip holder 30shown in FIGS. 15A, 15B and 15C is produced.

The supporting holes 14 and the gap in which the cutter wheel chip 22 islocated may be produced by grinding or by any other appropriate method.

The chip holder 30 has the supporting hole 14 through the axial centerof the chip receiver 17. The chip receiver 17 is opened at the bottomalong the axial direction of the chip receiver 17.

Except for the points described above, the chip holder 30 hassubstantially the same structure as that of the chip holder 10 shown inFIG. 2.

The chip holder 30 has an improved size precision and is more greatlyalleviated from deformation caused by impact or the like, as comparedwith the chip holder 20 shown in FIGS. 13A, 13B and 13C which isproduced by assembling the side walls 11 and the top portion 12 usingscrews. Therefore, the chip holder 30 can hold the cutter wheel chip 22more stably for a longer time and therefore allows the cutter wheel chip22 to scribe a brittle object stably for a longer time.

The supporting holes 14 are formed in the axial center of the chipreceivers 17, and the side portions of the rotating shaft 23 arerespectively supported by the entire portions of the chip receivers 17projecting from the side walls 11. As compared with the chip holder 20shown in FIGS. 13A, 13B and 13C in which the inner diameter of the chipreceivers 17 is larger than the diameter of the supporting holes 14 andthus the rotating shaft 23 is supported by the supporting holes 14, thechip holder 30 supports the rotating shaft 23 by a greater length andthus significantly improves the impact resistance and destructionresistance.

It is preferable to form the grooves 17 a as shown in FIGS. 14A and 14Bon the inner face of each chip receiver 17 in, for example, a verticaldirection and a horizontal direction. Cullet, dust or the like generatedwhile the brittle object is scribed is scattered through the grooves 17a. Therefore, the cullet, dust or the like is prevented from enteringbetween the cutter wheel chip 22 and the chip receivers 17 a to causethe cutter wheel chip 22 and the chip receivers 17 a to be immovablewith respect to each other. Thus, the chip holder can scribe a brittleobject more stably and extend the life of the edge of the cutter wheelchip 22.

The inner face of the chip receiver 17 which is to contact the cutterwheel chip 22 may be treated with DLC (diamond-like coating) in order toimprove resistance against wear or slipperiness. As such, the cutterwheel chip 22 rotates more smoothly, resulting in formation of morestable scribe lines and longer life of the cutter wheel chip 22.

INDUSTRIAL APPLICABILITY

As described above, the present invention provides a chip holder forrealizing long and stable use of a rotating shaft engaged with a cutterwheel chip and for allowing the cutter wheel chip to stably scribe asurface of a brittle object.

1-18. (canceled)
 19. A chip holder for holding a rotating shaft which isinserted through an axial center of a cutter wheel chip for scribing abrittle material, the chip holder comprising: a pair of side wallshaving respective supporting holes into which side portions of therotating shaft are respectively inserted; and a top portion connectingupper portions of the pair of side walls, wherein the pair of side wallsand the top portion are Integrally formed.
 20. A chip holder accordingto claim 19, wherein a chip receiver for preventing the cutter wheelchip from abrading due to contact with the side walls is provided on aface of each side wall facing the cutter wheel chip.
 21. A chip holderaccording to claim 19, wherein each supporting hole is provided with agroove along an axial direction of the rotating shaft.
 22. A chip holderaccording to claim 20, wherein a groove is provided on a face of thechip receiver facing the cutter wheel chip.
 23. A chip holder accordingto claim 19, wherein the supporting hole is formed by wire discharge.